Keywords: theropod,Sinosauropteryx, collagen, protofeather

(a) Microscopy of the integumental structures

The integumental structures in the newSinosauropteryx specimen occur as high-fidelity mineralized impressions (SEM on less rare Jehol biota soft-tissue specimens show pyrite as a consistently important mineral component;Leng & Yang 2003). The structures occur in several areas (figure 1a) comparable to that of the holotype NIGP 127586 (figure 1b) and NIGP 127587, including in a recess left by the proximal part of the tail (site 1;figures 1a, 2a,b and3a,b), along the neck (site 2;figure 2c), back and the distal part of the tail (sites 3 and 4;figures 2d–f and3c,d); also overlying well-preserved vertebrae (figure 2b). We also show identical structures inSinosauropteryx NIGP 127587 (figure 4). Unravelling the nature of the preserved integumental structures in IVPP V12415, as in the other specimens, is complex but we suggest the same structures occur in the skin and frill (figures 2 and3).

In site 1 (tail recess, see above), the regular, compact pattern of the preserved structures indicate they were part of the skin. Along the dorsal ascending part of the tail recess, within a slight concavity (figure 2a,b, black arrows inb), the integumental structures extend in rows parallel to the long axis of the tail (figure 3a). In extant animals (Lingham-Soliar 2005a,b) and in an ichthyosaur (Lingham-Soliar & Plodowski 2007), dermal collagen fibres orient in the same direction in numerous consecutive layers. Both patterns are consistent with the structural organization of dermal collagen. Towards the central, more exposed part of the tail recess, the integumental structures become fragmented, disorganized and scanty (figure 3a). As in ourSinosauropteryx, NIGP 127587 also shows clear signs of a recess formed by the proximal part of the tail (Chenet al. 1998) and it is probable that the fibres therein also emanate from the skin.

Figure 3a provides a crucial insight into the nature of the integumental structures as well as into the process of degradation (note that the terms degrade or degradation define both biological and geological erosion and are especially useful where such distinctions are difficult). Breakdown into disorganized structures is initiated in the tissue. The degradation may be exacerbated during fossilization by the agents of erosion, e.g. wind and water especially in the more exposed central area of the preservation (site 1). In addition, fragments of decomposing tissue may have been better protected in niches rather than exposed areas. We observe the inception of degradation inSinosauropteryx NIGP 127587 (figure 4b, arrows) from geometrically precise bands of parallel integumental structures, oriented at acute angles to the tail's long axis (figure 4a, arrows 1–4). These bands are evidently the remnants of a finely assembled fibre architecture occurring in several bands of overlying layers (figure 4a, arrowhead shows overlap) consistent with structural reinforcement of the skin (Lingham-Soliar 2005a,b). Fibres between the chevrons extend parallel to the long axis of the tail and probably represent the skin or longitudinal musculature. The inception of the break-up of the fibre architecture, i.e. just a few loose fibres (figure 4b, arrows) is analogous to short stitches pulled from clothing during wear. It is a clear indication of how the aberrant integumental structures (whether from skin, muscle or frill), popularly referred to as protofeathers, originated.

Fibres preserved over caudal vertebrae in the proximal part of the tail (adjacent to site 1;figure 2b, detail infigure 3b₇) occasionally formed aberrant associations with others. In site 2, where the neck arches strongly over the body, there are two discrete groups of fibres; the first located distally is oriented at right angles to the second (figure 2c, numbered 1 and 2, respectively), which lies adjacent to the cervical vertebrae. This vital preservation provides compelling evidence concerning the origin of coronal fibres (fibres peripheral to the body outline). Directly adjacent to the cervical vertebrae, the non-coronal soft tissue apparently represents part of the skin or epaxial musculature (Longissimus cervico-capitis), its fibres (beaded) extend parallel to the neck's long axis (figure 2c, detail) in striking contrast to those of the distal soft tissue, which lie at right angles to them. In the holotype, restriction of the integumental structures to a corona was thought to be a preservational bias (Currie & Chen 2001), i.e. the marginal substrate provided better conditions for soft-tissue preservation, which is clearly not the case here where fibres are also preserved within the body outline (also at site 1 and in NIGP 127587). The sharp demarcation of the distal fibres along the animal's margin may be considered therefore a primary condition, not connected with any preservational bias. Protofeathers in such circumstances would have a high probability of more random points of origin and orientations and not the clean-cut corona noted. The most parsimonious explanation with respect to the above observations is that the marginal fibres belonged to a frill. Furthermore, the fibres nearest to the juncture between the neck and body converge distally more or less to a point probably a consequence of the frill being somewhat squashed as the neck arched strongly backward during rigour mortis. Despite this, these long fibres retain a remarkable straightness (figure 2c, arrowheads), consistent with high tensile stiffness and protection within the collagenous matrix of a frill. Such features are almost identical in the holotype (Nature,doi:10.1038/34356). The improbability that these fibres represent ‘protofeathers’, described as ‘soft and pliable’ (Currie & Chen 2001), and that they escaped becoming tangled and matted in the mud prior to fossilization, is evident (see alsofigure 3d).

Although the frill is poorly preserved over the animal's back, traces of fibres sharply angled away from the body are evident in the shoulder and sacral area (see below; arrows,figure 1a). Integumental structures at the tip of the tail are also considered to belong to the frill (sites 3 and 4). In our specimen, as well as in the holotype (our observations,figure 1b), the fibres in the distal tail occur in regularly spaced patches, which we believe is a primary condition consistent with the gaps in a scalloped frill (figure 2d). Along the terminal vertebrae (figure 3c), the lower parts of the integumental structures (approx. half their lengths) across a broadband are barely distinguishable, compacted together as in a matrix of connective tissue, becoming discernible towards the mid-point (figure 3d, circle), and separating as they degrade or become ‘unglued’ (Lingham-Soliar 2003b) at the tips. Such features are comparable with stages in the degradation of collagenous architectures in decomposing dolphin hypodermis (Lingham-Soliar 2003b). We would expect protofeathers to be rather sparse at this terminal part of the tail where the skin would be thinnest.

Our results show no herringbone patterns connected with the integumental structures or patterns that might resemble the plumules of birds (Currie & Chen 2001), but rather that the patterns are of geometrically precise bands of parallel fibres (figure 4). Short, randomly oriented, sinuous strands, interpreted as protofeathers (Currie & Chen 2001), are demonstrably a consequence of the degradation of the regular structures of bands of parallel fibres (figures 3a and4). The geometric pattern noted is maintained so long as there is tension in the tissue whether this is in the skin, muscle or frill. Once tension is lost, the fibres may take on a sinuous appearance (Gordon 1978;Lingham-Soliar 2003a,b).

(b) Thickness measurements of the integumental structures

Isolated integumental strands (figures 2b and3b) from site 1 of ourSinosauropteryx show a distinct beaded structure. The strands range in thickness from 80 to 120 μm, but rarely as thin as 65 μm as infigure 3b₃ (mean, 88 μm;n=100; s.d., 14.98). Over the caudal vertebrae, the thickness ranged from 50 to 95 μm (mean, 71.3 μm,n=75; s.d., 11.24). These measurements were consistent for the other sites. Some strands lie close to or overlie others as would be expected during the process of decay and decomposition (Lingham-Soliar 2001,2003a,b;Feducciaet al. 2005;figure 2b, white arrows and circle andfigure 3b₅).Figure 3b₇ shows swelling towards the centre of the integumental structure indicating the probable onset of diagenetic transformations, which include distortion in shape and thickness (Allison 1988a,b;Allison & Briggs 1991;Lingham-Soliar 2001,2003b;Briggs 2003), cautioning that measurements be treated as approximations.

(a) Structure of the fibres

Under close-up examination, the integumental structures frequently show remarkable straightness (figure 3b_1–3,6–8), consistent with high tensile fibres, whereas sinuousness (figure 3b₄) was more infrequent. All integumental structures examined show the beaded form noted, e.g. in collagen fibre bundles in the dermis of sharks (Lingham-Soliar 2005a,b), modern-day reptiles (Lingham-Soliar inFeducciaet al. 2005), ichthyosaurs (Lingham-Soliar 1999,2001) and dinosaurs (Feducciaet al. 2005) as well as individual mammalian collagen fibrils (Reichlinet al. 2005). Beading in histological preparations of collagen fibre bundles is thought to occur during dehydration with contraction in regular short waves of approximately 50 μm, more or less, dependant on the thickness of the fibre bundle (Lingham-Soliar 2003b). A tendency for collagen fibres to twist into rope-like structures (Young 2003) may also account for the beaded appearance. However, we emphasize that our objective is primarily to show that the integumental structures inSinosauropteryx are structural fibres of soft tissue which form characteristic patterns in a wide variety of animals (Feducciaet al. 2005) and that they are collagenous is of secondary importance.

(b) Preservational biases during an animal's taphonomic history

Preservational bias of fibres, e.g. occurrence in one well-preserved specimen and not in another is one of the enigmas of fossilization frequently noted in different specimens. For example, in the ichthyosaurStenopterygius dermal fibres were preserved over vertebrae and substrate in one soft-tissue specimen but solely within the body in another (Lingham-Soliar 2001) and similar differences are noted in soft-tissue preservation in the twoPsittacosaurus specimens mentioned above (Mayret al. 2002; Lingham-Soliar inFeducciaet al. 2005). Preservation of a hypothesized frill occurs in our specimen over the neck and tail (with scanty remains over the animal's back). In the holotype (Chenet al. 1998), it is virtually complete from the neck to the tip of the tail (figure 1b). Differences of preservation may depend, e.g. on how much of the animal was imbedded in the sediment (mud) immediately after death. For instance, among the many complexities of preservation (Briggs 2003), if the frill at the highest part of an animal lying on its side, i.e. the body and thicker part of the tail, was not rapidly and completely imbedded in the sediment (a possible fate in our specimen) then rapid degradation and destruction of the frill may occur by e.g. mechanical agents (albeit not exclusively) such as wind, water and scavengers. Initially, the matrix of the frill would permit the fibres a good degree of tension, but with decomposition, this tension will inevitably be lost.

(c) Functional consequences of skin stiffness

InSinosauropteryx, with the longest tail known for any theropod (Jiet al. 2001), the caudal vertebrae are not especially modified for stiffness as inDeinonychus (Weishampelet al. 1990). A fibre-reinforced skin, which, e.g. may account for 40–50% total tail stiffness in sharks (Wainwrightet al. 1976;Lingham-Soliar 2005b), may have helped to maintain a stiff tail inSinosauropteryx. In addition to a decorative role, perhaps the primary function of the tail frill inSinosauropteryx was one of stiffness.

In both the nature of the fibrous structures and the structural architectures (geometrically parallel) they comprise inSinosauropteryx (e.g.figures 3a and4), they compare with collagenous fibre reinforcements of the dermis in living animals (Feducciaet al. 2005 and references therein;Lingham-Soliar 2005a,b). We suggest therefore that they were collagenous. As in many vertebrates including modern reptiles, the collagen probably occurred in numerous layers of the skin (Feducciaet al. 2005;Lingham-Soliar 2005a,b;Lingham-Soliar & Plodowski 2007), which would account for their density in preserved material (Chenet al. 1998;Currie & Chen 2001). The relatively inextensible nature of collagen makes it an ideal material for fibre architectural systems and accounts for its ubiquitous occurrence in the skin of vertebrates and invertebrates (Gordon 1978; Lingham-Soliar inFeducciaet al. 2005). In a unique preservation of a cross-section into the skin of a psittacosaur, more than 25 layers of fibres are observed (T. Lingham-Soliar 2007, unpublished results). We propose that multiple layers of collagen in the skin of dinosaurs function to stiffen the tissue at high strain and, importantly, provide toughness against injury, which would be particularly useful in less heavily armoured dinosaurs.

(d) Biological and evolutionary implications of a fibre-reinforced skin in dinosaurs

The pervasiveness of the beguiling, yet poorly supported, proposal of protofeathers inSinosauropteryx has been counterproductive to the important question of the origin of birds. For instance,Juravenator (Gohlich & Chiappe 2006), a new Solnhofen compsognathid closely related toCompsognathus andSinosauropteryx, as well as re-examined French TithonianCompsognathus corallestris (Peyer 2006) were not only devoid of any trace of protofeathers/feathers, but had fairly typical tuberculated dinosaur skin (Gohlich & Chiappe 2006). Although a severe setback to the view that coelurosaurs possessed feathers,not scales, the authors (Gohlich & Chiappe 2006) challenge their own evidence by proposing that coelurosaurs ‘may have differed greatly in the extension of their feathery covering’, from ‘for the most part feathered’ inSinosauropteryx to scantily feathered inJuravenator. Evenif plausible, the unwillingness to consider the realistic alternative that coelurosaurs may simply have been scaly theropods is a cause for concern.

As inSinosauropteryx, proposals that integumental structures preserved inSinornithosaurus (Xuet al. 2001) and tyrannosauroids (Xuet al. 2004) are the remains of protofeathers/feathers do not withstand scientific scrutiny (Lingham-Soliar inFeducciaet al. 2005). On the other hand,Sinosauropteryx IVPP V12415 provides a remarkable opportunity to understand dermal and subdermal fibre reinforcements in dinosaurs and helps to further our insights into taphonomic processes (Allison & Briggs 1991) without recourse to arbitrary conjectures on feather origins.

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